KR102243534B1 - Smart distribution board management system for disaster safety - Google Patents

Abstract

The present invention relates to a disaster safety type smart switchboard management system and, more particularly, to a disaster safety type smart switchboard management system that transmits disaster detection data of a disaster detection module installed around a switchboard to a remote server to comprehensively analyze disaster risk levels for a fire, earthquake, and the like, provides notification services such as alarms and text messages to an administrator, and cuts off emergency power in a remote control or automatic control method according to the risk levels. The disaster safety type smart switchboard management system comprises: a disaster detection module (100); a gateway (200); a remote server (300); and a device (400).

Description

Smart distribution board management system for disaster safety

The present invention relates to a disaster-safe smart switchgear management system, and more specifically, by transmitting the disaster detection data of the disaster detection module installed around the switchboard to a remote server to comprehensively analyze the stages of disaster risk such as fire and earthquake, and manage it. It relates to a disaster-safe smart switchgear management system that provides notification services such as alerts and text messages to users, and cuts off emergency power by remote control or automatic control method according to a risk level.

In general, electrical equipment such as switchgear is a device that converts and supplies high-voltage power provided by KEPCO into low-voltage power to provide high-voltage power provided by KEPCO to homes, factories, and schools.

Since the switchgear handles high-voltage power, high quality is required in terms of safety and durability.

The interior of the switchgear can be largely divided into a part that processes high-voltage power and a part that processes low-voltage power. For example, a part receiving power from KEPCO may be divided into a high-pressure treatment unit, and a part that converts and distributes power to low pressure may be divided into a low-pressure treatment unit. In other words, since the voltage is converted from high to low pressure as needed, more than a certain amount of heat is generated inside the electrical equipment, and depending on the environment in which the electrical equipment is installed or the degree of aging, it becomes increasingly vulnerable to heat or the degree of heat increases beyond the standard. As a result, there is a problem that some of the electrical equipment is deteriorated or abnormality occurs.

In recent years, earthquakes have occurred frequently in Korea, and it is difficult to actively respond to disasters simply by designing with reinforced seismic functions for electrical facilities such as switchboards, and it is necessary to operate safely or intelligently respond to disasters in case of disasters such as earthquakes. .

In other words, in the event of a disaster such as an earthquake or fire, a disaster response plan is required to minimize the damage. Moreover, if a problem occurs in the control device itself that controls each facility, it is immediately prepared for disasters for electrical facilities. It is difficult to control, so a countermeasure is needed.

An example of a technique for solving this problem is disclosed in Document 1 below.

In Patent Document 1, in the switchgear provided with a seismic device on the bottom surface, the earthquake detection unit is installed in the switchgear to detect vibration caused by the earthquake; A deformation detection unit installed inside the switchgear to detect deformation of the structural frame due to an external force such as an earthquake; A position sensing unit installed on the bottom of the switchgear and detecting whether to return after being moved to a predetermined distance position by a seismic device when an earthquake occurs; A fire detection unit installed inside the switchgear and detecting whether or not a fire occurs by sensing an internal temperature; A power cut-off unit that cuts off power supplied to the switchgear; A control unit for receiving information transmitted from the earthquake detection unit, deformation detection unit, position detection unit, and fire detection unit, and controlling an operation of the power cut-off unit based on the received information; A wireless communication unit that selectively transmits control information of the switchgear to the mobile terminal of the manager or the management server; An information output unit installed on an outside side of the switchboard and outputting information controlled by the control unit; And a power supply unit comprising a regular power supply unit for supplying power to the control unit from a power device installed inside the switchboard, and an auxiliary power unit supplying power to the control unit when the switchboard is turned off. Disclosed is a switchgear equipped with a self-diagnosis function.

However, in the conventional technology as described above, attempts have been made to detect fire and earthquakes with various sensors such as a temperature sensor, a smoke sensor, and a vibration sensor in the switchboard. There is a problem that there is a problem that there is a problem that there is a problem that there is a problem that there is insufficient time for prompt alarm generation because it is possible to detect only when a disaster risk reaches the location where the sensor is installed because it is difficult to determine the external environment such as the problem.

In addition, in the event of a fire, there is a problem in that all information on the status of the switchboard as well as the switchboard by various sensors is lost, and the cause of the fire cannot be determined.

Republic of Korea Patent Publication No. 10-1957409 (registered on March 6, 2019)

The present invention has been devised to solve the above-described problems, and provides simplicity of installation and maintenance by converting sensors such as temperature, humidity, carbon dioxide, smoke, flame, vibration, and tilt to a PCB module for monitoring a disaster. The purpose is to provide a disaster-safe smart switchgear management system that can secure stability.

In addition, even when a disaster such as fire or earthquake occurs in the switchboard, it is possible to store and back up the disaster detection data of the switchboard without loss, and a redundant concept of disaster-safety smart that can transmit the stored disaster detection data of the switchboard to a remote server. The purpose is to provide a switchgear management system.

In order to achieve the above object, the disaster-safe smart switchgear management system according to the present invention is installed in a short-range communication module 110 that is connected through short-range wireless communication and transmits sensing information, and a plurality of switchboards are installed to prevent the disaster of the switchboard. A sensing module 120 that detects the occurrence of a situation in real time, and a control module that transmits and receives the disaster detection data output from the sensing module 120 to the gateway 200, and cuts off the power of the switchboard based on the received control signal. Disaster detection module 100 including (130); Having at least one wired/wireless communication module, collects disaster detection data output from the plurality of disaster detection modules 100 through the wired/wireless communication module using wired/wireless communication, and collects disaster detection data using wired/wireless communication A gateway 200 provided to the remote server 300; A remote server 300 that is connected to the gateway 200 through a wired/wireless router and a communication network, and stores and compares and analyzes the disaster detection data collected in the gateway 200; And an external monitoring device 400 provided at a location spaced apart from the switchboard to collect and store and back up disaster detection data output from the disaster detection module 100, and the sensing module 120 A temperature sensor 121 for measuring the temperature of the switchboard, a humidity sensor 122 for measuring the humidity of the switchboard, a smoke detection sensor 123 for detecting smoke generated in the event of a fire, and a flame generated in the event of a fire. A flame detection sensor 124, a carbon dioxide sensor 125 for measuring carbon dioxide inside the switchboard, a vibration sensor 126 for detecting vibration due to an earthquake, and a tilt sensor 127 for detecting the tilt of the switchboard due to earthquake. Characterized in that.

In addition, the external monitoring device 400 is connected to the disaster detection module 100, the first communication unit 410 for transmitting and receiving disaster detection data of the switchboard; A second communication unit 420 connected to the remote server 300 to remotely transmit and receive disaster detection data; A control unit 430 that receives various signals from the first communication unit 410 and the second communication unit 420 and processes logic by a program; A power supply unit 440 supplying power to the control unit 430; A signal conversion unit 450 connected to the disaster detection module 100 to convert an analog signal received into a digital signal and transmit a control command by the control unit 430; A transmission unit 460 for transmitting a signal input through the signal conversion unit 450 to a remote server 300 through an Internet communication network; And a backup unit 470 that backs up and stores the disaster detection data transmitted from the control unit 430 and transmits the stored backup data to the remote server 300.

In addition, the control unit 430 may include an output unit 431 for outputting disaster detection data of the switchgear; A display unit 432 for displaying disaster detection data of the switchgear output from the output unit 431 on a screen; A memory unit 433 for storing disaster detection data of the switchgear; And comparing and analyzing the disaster detection data of the switchgear with a preset threshold value, transmitting the analyzed data value to the remote server 300, and according to the self-analyzed data value or an event occurrence signal output from the remote server 300. It characterized in that it comprises a; analysis control unit 434 for generating an alarm signal.

In addition, the remote server 300 receives the disaster detection data value sensed through the disaster detection module 100 and registers it in a database, and the data collection module 310 collected through the data collection module 310 A diagnosis module 320 for diagnosing the occurrence of a disaster in the switchboard by analyzing the disaster detection data value, the disaster detection data values collected through the data collection module 310 and the disaster diagnosis diagnosed through the diagnosis module 320 And a visualization module 330 that visualizes and provides information to the manager terminal 500 connected through a communication network, and the diagnosis module 320 includes the current temperature and humidity of the switchgear collected through the data collection module 310, Disaster detection data values for smoke concentration, carbon dioxide concentration, vibration intensity, X-axis, Y-axis, and Z-axis tilt are compared with each set threshold value, and if the current disaster detection data value exceeds the threshold value, the corresponding switchboard is disaster. It is characterized in that it is diagnosed and displayed as having occurred.

In addition, a disaster response application is mounted and provided by the administrator, and the distribution panel status information, disaster occurrence signal detection information, and emergency situation occurrence information transmitted from the remote server 300 are displayed on the application. It is characterized.

In addition, the remote server 300 induces inspection by the administrator by sending a text to the administrator terminal 500 for daily inspection and detection of danger signals according to the disaster monitoring step, and in the dangerous entry phase, the administrator performs remote control or manual control. The power is cut off by means of an emergency situation, and the power is cut off by automatic control.

In addition, it is characterized in that it further includes a rechargeable auxiliary battery in case a natural disaster or a human disaster occurs and the power supply of the switchgear is cut off.

As described above, the disaster-safe smart switchgear management system according to the present invention transmits the disaster detection data of the switchgear output from the disaster detection module to the server through wired or wireless to comprehensively analyze the stages of disaster risk such as fire and earthquake, and the manager It provides notification services such as alerts and text messages to users, and has the effect of preventing disasters as well as secondary accidents caused by this by turning off emergency power by remote control or automatic control method according to steps.

In addition, even when a disaster such as a fire or earthquake occurs in the switchboard, it is possible to store and back up the disaster detection data of the switchboard without loss, so that it is possible to identify and analyze the cause of the fire by securing the site record of the switchboard. .

1 is a conceptual diagram for explaining a disaster safety smart switchgear management system according to the present invention.
Figure 2 is a configuration diagram showing a disaster detection module according to the present invention.
3 is a block diagram showing a remote server according to the present invention.
Figure 4 is a configuration diagram showing an external monitoring device according to the present invention.

Hereinafter, in order to describe in detail enough to allow those of ordinary skill in the art to easily implement the present invention, the most preferred embodiment of the present invention will be described in detail.

As shown in FIG. 1, the disaster-safe smart switchgear management system according to the present invention includes a disaster detection module 100, a gateway 200, a remote server 300, and an external monitoring device 400.

The disaster-safe smart switchgear management system configured as described above transmits disaster detection data by the disaster detection module 100 installed around the switchgear to the remote server 300 to comprehensively analyze the stages of disaster risk such as fire and earthquake, and manage it. It will provide notification services such as alerts and text messages to users.

In particular, even when a disaster such as a fire or an earthquake occurs in the switchboard through the external monitoring device 400, status information of each switchboard can be stored and backed up without loss of the disaster detection data of the switchboard.

As shown in Fig. 2, the disaster detection module 100 is installed in a short-range communication module 110 that is connected through short-range wireless communication to transmit sensing information, and a plurality of switchboards arranged to generate a disaster situation of the switchboard. A sensing module 120 for real-time sensing, and a control module 130 that transmits and receives the disaster detection data output from the sensing module 120 to the gateway 200, and cuts off power to the switchboard based on the received control signal. ).

The short-range communication module 110 is connected to the gateway 200 through a communication network and transmits sensing information.

The sensing module 120 includes a temperature sensor 121 for measuring the temperature of the switchboard, a humidity sensor 122 for measuring the humidity of the switchboard, a smoke detection sensor 123 for detecting smoke generated in the event of a fire, and a fire. A flame detection sensor 124 for detecting the generated flame, a carbon dioxide sensor 125 for measuring carbon dioxide inside the switchboard, a vibration sensor 126 for detecting vibration due to an earthquake, and a slope for detecting the slope of the switchboard due to an earthquake It includes a sensor 127.

The control module 130 transmits the disaster detection data output from the sensing module 120 to the gateway 200 through the short-range communication module 110, and received from the gateway 200 through the short-range communication module 110. Shut off the power of the switchgear based on the control signal. To this end, the control module 130 is electrically connected to the sensing module 120 and the short-range communication module 110.

In this way, the disaster detection module 100 collects various types of disaster information that can confirm the occurrence of a disaster situation of the switchgear through the sensing module 120 installed in the switchboard and detects whether a disaster has occurred, including a fire, an earthquake, and the like. In addition, the disaster detection module 100 may recognize a disaster situation by communicating with the Ministry of Public Safety and Security server.

The gateway 200 includes at least one wired/wireless communication module, and collects disaster detection data of the switchgear output from the plurality of disaster detection modules 100 through the wired/wireless communication module using wired/wireless communication, and collected. Data is provided to the remote server 300 using wired or wireless communication.

The remote server 300 is connected to the gateway 200 through a wired/wireless router and a communication network, and stores and compares and analyzes the disaster detection data collected in the gateway 200.

The remote server 300 receives and stores disaster detection data from the gateway 200 so that all disaster detection data transmitted from the disaster detection module 100 to the gateway 200 can be collected and managed. ) Is connected through a wired/wireless router and a communication network. At this time, since each disaster detection data is given an identification symbol that can identify the disaster detection module 100 that provided the information, the remote server 300 may classify and store the disaster detection data for each disaster detection module 100. .

If necessary, the remote server 300 may receive and store a control signal generated from the gateway 200 as well. At this time, since each control signal is given an identification symbol for identifying the disaster detection module 100 to be provided with the control signal, the remote server 300 may classify and store the control signal for each disaster detection module 100.

As shown in Fig. 3, the remote server 300 receives the disaster detection data value detected through the disaster detection module 100 and registers it in a database, and the data collection module ( A diagnostic module 320 for diagnosing the occurrence of a disaster in the switchgear by analyzing the disaster detection data values collected through 310), and the disaster detection data values collected through the data collection module 310 and the diagnostic module 320 And a visualization module 330 that visualizes and provides disaster diagnosis information diagnosed through the communication network to the manager terminal 500 connected through the communication network.

Here, the diagnosis module 320 is the current temperature and humidity of the switchgear, smoke concentration, carbon dioxide concentration, vibration intensity, and disaster detection data for the X-axis, Y-axis and Z-axis slopes collected through the data collection module 310 The value is compared with each set threshold value, and if the current sensing value exceeds the threshold value, it is diagnosed and displayed as a disaster in the corresponding switchgear.

The external monitoring device 400 may be provided at a location separated from the switchboard to collect disaster detection data output from the disaster detection module 100, and store and back up the data.

As shown in FIG. 4, the external monitoring device 400 includes a first communication unit 410, a second communication unit 420, a control unit 430, a power supply unit 440, a signal conversion unit 450, and a transmission unit 460. ) And a backup unit 470.

The external monitoring device 400 configured as described above can store and back up the disaster detection data of the switchgear even when a disaster such as a fire or an earthquake occurs in the switchboard without loss.

In addition, the external monitoring device 400 is equipped with a function to detect when a singularity occurs in the monitoring screen of the switchgear in real time, and displays and informs the administrator of the specificity.

The first communication unit 410 is connected to the disaster detection module 100 to transmit and receive disaster detection data of the switchboard.

The first communication unit 410 communicates with each of the disaster detection modules 100 through CAN communication, and the temperature and humidity around the switchgear, smoke concentration, and carbon dioxide concentration detected by the disaster detection module 100, Data such as vibration intensity, X-axis, Y-axis, and Z-axis tilt values are transmitted and received to the controller 430.

The second communication unit 420 is connected to the remote server 300 to remotely transmit and receive disaster detection data of the switchboard.

The second communication unit 420 communicates with the remote server 300 through Ethernet communication. Accordingly, the remote server 300 can monitor whether a disaster has occurred in each switchboard, and a failure or occurrence of various events can be quickly notified to the remote server 300.

The control unit 430 receives various signals from the first communication unit 410 and the second communication unit 420 and processes logic by a program. In addition, the control unit 430 may collect and store disaster detection data at a location spaced apart from a plurality of switchgear.

The control unit 430 includes an output unit 431 that outputs disaster detection data of the switchgear, a display unit 432 that displays disaster detection data of the switchgear output from the output unit 431, and detects the disaster of the switchgear. The memory unit 433 storing data and the disaster detection data of the switchboard are compared and analyzed with a preset threshold value, and the analyzed data value is transmitted to the remote server 300, and the self-analyzed data value or the remote server 300 ) And an analysis control unit 434 that generates an alarm signal according to the event occurrence signal output from).

For example, through the analysis control unit 434, the disaster detection data of the switchboard may be compared and analyzed with a preset threshold value to determine whether a disaster has occurred. In this process, if an event (disaster) has occurred in a specific switchgear section, additional information such as a disaster situation occurrence or time information of the switchboard can be matched and stored. Accordingly, the user can select a specific switchboard and easily search for an event occurring in a corresponding time period.

The power supply unit 440 serves to supply power to the control unit 430. The supplied power is transmitted from the control unit 430 to the output unit 431, the display unit 432, the memory unit 433 and the analysis control unit 434.

The signal conversion unit 450 converts an analog signal received by being connected to the disaster detection module 100 to a digital signal, and transmits a control command by the control unit 430.

The signal conversion unit 760 is an ADC that converts analog signals output from each sensor of the disaster detection module 100 into a digital signal, and a PWM signal generation that generates a PWM signal according to a control signal output from the control unit 430 Includes wealth.

The transmission unit 460 transmits a signal input through the signal conversion unit 450 to the remote server 300 through an Internet communication network.

The transmission unit 460 communicates with the remote server 300 through Modbus TCP/IP communication. The TCP/IP data transmission method has the advantage of being able to transmit large amounts of data at high speed.

The backup unit 470 backs up and stores the disaster detection data transmitted from the control unit 430, and transmits the stored backup data to the remote server 300.

The backup unit 470 provides data requested by the remote server 300 for each virtual device, or the remote server 300 functions to write a control value or set value to a virtual device, and executes or stops a virtual device. Carry out.

As described above, according to the present invention, it is possible to store and back up disaster detection data of each switchboard from the outside, and remote transmission of the disaster detection data is possible, thereby increasing equipment reliability.

On the other hand, the present invention is equipped with a disaster response application is installed by the administrator, and the switchboard status information, disaster occurrence signal detection information, and emergency situation occurrence information transmitted from the remote server 300 is displayed on the application manager terminal 500. Includes.

The manager terminal 500 is provided by a site manager at a disaster site. The manager terminal 500 is equipped with a disaster response application.

The manager terminal 500 includes a portable terminal such as a smart phone or a tablet PC, and a call is possible through a call button.

The manager terminal 500 receives switchboard status information, disaster signal detection information, and emergency situation occurrence information from the remote server 300, and on the application of the manager terminal 500, the switchboard status information, disaster signal detection information, and emergency Situation information is displayed.

On the other hand, the remote server 300 induces inspection by the administrator by sending a text to the administrator terminal 500 for daily inspection and detection of danger signals according to the disaster monitoring step, and in the dangerous entry phase, the administrator performs remote control or manual control. The power is cut off by means of an emergency, and the power is cut off by automatic control in case of an emergency.

The present invention may further include an auxiliary battery of a charging method in case a natural disaster or a human disaster occurs and the power supply of the switchgear is cut off. That is, the auxiliary battery serves to supply auxiliary power when power is not supplied to the switchgear.

Although the present invention has been described based on a preferred embodiment with reference to the accompanying drawings, it is apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the present invention from this description. Accordingly, the scope of the present invention should be interpreted by the claims set forth to include examples of such many modifications.

100: disaster detection module 110: short-range communication module
120: sensing module 121: temperature sensor
122: humidity sensor 123: smoke detection sensor
124: flame detection sensor 125: carbon dioxide sensor
126: vibration sensor 127: tilt sensor
130: control module 200: gateway
300: remote server 310: data collection module
320: diagnostic module 330: visualization module
400: external monitoring device 410: first communication unit
420: second communication unit 430: control unit
431: output unit 432: display unit
433: memory unit 434: analysis control unit
440: power supply unit 450: signal conversion unit
460: transmission unit 470: backup unit
500: administrator terminal

Claims (7)

A short-range communication module 110 that is connected through short-range wireless communication to transmit sensing information, a sensing module 120 that is respectively installed in a plurality of switchboards to detect the occurrence of a disaster situation in the switchboard in real time, and the sensing module ( Disaster detection module 100 including a control module 130 for transmitting and receiving the disaster detection data output from 120 to the gateway 200, and cut off power to the switchboard based on the received control signal;
It has at least one wired/wireless communication module, collects disaster detection data output from the disaster detection module 100 through the wired/wireless communication module using wired/wireless communication, and collects the collected disaster detection data at a remote location using wired/wireless communication. A gateway 200 provided to the server 300;
A remote server 300 that is connected to the gateway 200 through a wired/wireless router and a communication network, and stores and compares and analyzes disaster detection data collected in the gateway 200; And
Includes; an external monitoring device 400 provided at a location spaced apart from the switchboard and collecting disaster detection data output from the disaster detection module 100, storing and backing up the data,
The sensing module 120 includes a temperature sensor 121 for measuring the temperature of the switchboard, a humidity sensor 122 for measuring the humidity of the switchboard, a smoke detection sensor 123 for detecting smoke generated in the event of a fire, and a fire. A flame detection sensor 124 for detecting the generated flame, a carbon dioxide sensor 125 for measuring carbon dioxide inside the switchboard, a vibration sensor 126 for detecting vibration due to an earthquake, and a slope for detecting the slope of the switchboard due to an earthquake Including a sensor 127,
The external monitoring device 400 is connected to the disaster detection module 100, the first communication unit 410 for transmitting and receiving disaster detection data of the switchboard;
A second communication unit 420 connected to the remote server 300 to remotely transmit and receive disaster detection data;
A control unit 430 that receives various signals from the first communication unit 410 and the second communication unit 420 and processes logic by a program;
A power supply unit 440 supplying power to the control unit 430;
A signal conversion unit 450 connected to the disaster detection module 100 to convert an analog signal received into a digital signal and transmit a control command by the control unit 430;
A transmission unit 460 for transmitting a signal input through the signal conversion unit 450 to a remote server 300 through an Internet communication network; And
Includes; a backup unit 470 for backing up and storing the disaster detection data transmitted from the control unit 430 and transmitting the stored backup data to the remote server 300,
The control unit 430 includes an output unit 431 for outputting disaster detection data of the switchgear;
A display unit 432 for displaying disaster detection data of the switchgear output from the output unit 431 on a screen;
A memory unit 433 for storing disaster detection data of the switchgear; And
The disaster detection data of the switchgear is compared and analyzed with a preset threshold value, and the analyzed data value is transmitted to the remote server 300, and an alarm according to the self-analyzed data value or an event occurrence signal output from the remote server 300 Disaster safety type smart switchgear management system comprising a; analysis control unit 434 for generating a signal.
delete delete The method according to claim 1,
The remote server 300 includes a data collection module 310 that receives the disaster detection data value detected through the disaster detection module 100 and registers it in a database, and the disaster detection collected through the data collection module 310 A diagnosis module 320 for diagnosing the occurrence of a disaster in the switchgear by analyzing data values, and the disaster detection data values collected through the data collection module 310 and the disaster diagnosis information diagnosed through the diagnosis module 320 It includes a visualization module 330 that visualizes and provides it to the manager terminal 500 connected through a communication network, and the diagnosis module 320 includes the current temperature and humidity of the switchgear collected through the data collection module 310, and smoke concentration. , CO2 concentration, vibration intensity, and disaster detection data values for the X-axis, Y-axis, and Z-axis inclinations are compared with the threshold values set respectively, Disaster safety type smart switchgear management system, characterized in that the diagnosis and display.
The method according to claim 1,
Disaster response application is mounted and provided by the administrator, characterized in that it comprises a manager terminal 500 that displays the status information of the switchboard, disaster occurrence signal detection information, and emergency situation occurrence information transmitted from the remote server 300 on the application. Disaster-safe smart switchgear management system.
The method of claim 5,
The remote server 300 induces inspection by the administrator by sending a text to the administrator terminal 500 for daily inspection and detection of danger signals according to the disaster monitoring step, and in the dangerous entry phase, the administrator powers by remote control or manual control. Disaster safety type smart switchgear management system, characterized in that the power is cut off by automatic control in case of an emergency situation.
The method according to claim 1,
Disaster-safe smart switchgear management system, characterized in that it further includes a charging-type auxiliary battery in case a natural or human disaster occurs and the power supply of the switchgear is cut off.

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